Multilayered insulation batt for building structures

Description

FIELD OF THE INVENTION

[0001] This invention relates to thermal insulation for residential or commercial building structures to provide a comfortable temperature for the occupants or objects within. This insulation material is typically installed in the exterior walls and in attic areas.

BACKGROUND OF THE INVENTION

[0002] It is known in the building construction industry to use any one of three types of insulation materials. These may be categorized by structure as being either loose fill-type, rigid panel type, or a flexible type commonly sold in blankets or batts which may be stored in rolls and cut to desired length at the installation site.

[0003] This last category, insulation batting, is the most common type used for insulating the walls and roof of home dwellings and other commercial structures. The insulation batt usually comprises a foil or kraft paper facing with a layer of low density fiberglass adhered thereto. The facing can provide a vapor barrier, a radiant energy reflector, and also a convenient means for attaching the insulation to structural components of the building. The layer of fiberglass insulation provides most of the insulating properties of the material which are generally expressed as an "R-value". The R-value is commonly dependent on a combination of either the depth of the insulation and/or its density. The thicker and more dense the insulating material, the greater its insulating capacity and hence the greater its R-value.

[0004] While numerous attempts have been made to increase the overall insulation performance in structures by using these three insulating methods, drawbacks include significantly increased cost due to the products themselves, the additional building materials required to use the products, and greater labor costs due to additional steps required in construction. The most economical form of insulation is the insulation batting or blanket. This material has the advantages of ease of handling, flexibility, fire resistance, and low cost. Unfortunately, it has a rather low R-value.

[0005] The prior art which most closely resembles the present invention is that of multiple reflective low emissivity insulation. The use of this type of insulation in the past has been restricted to very high temperature or very low temperature applications, such as cryogenics, and provides effective insulation across extreme temperature gradients. Furthermore, these prior technologies require the use of a great number of low emissivity layers, as many as 100 per inch. In addition, these insulating systems require that the space between reflective layers be evacuated in order to eliminate heat transfer by conduction or convection. Often they include a spacer material between the reflective layers in order to prevent the layers from contacting each other and thereby creating "thermal bridges". These systems have also included the insertion of radiant energy absorbing and refracting material into the evacuated space between the reflective layers in order to further reduce heat transfer by radiation. Insulating systems of this type are described in U.S. Patent No. 3,124,853; 3,151,364 to P.E. Glaser et al and GB-A-853585. Naturally, the requirements of these systems for evacuating the spaces between reflective layers is not practical for building structures.

[0006] There are some products available for building structures which utilize a number of reflective layers with an air space between the layers. However, these systems are only effective in retarding heat transfer due to radiation. Heat transfer due to conduction and convection are allowed to occur freely by movement of air molecules between the reflective layers. The relatively low R-value of these systems, along with the specialized installation techniques involved, have restricted their widespread use in building structures.

[0007] Additionally, there are insulation products which employ a single layer of low heat conductivity material, such as foam or fiberglass, along with a reflective material adhered to both sides of the low heat conductivity material (c.f. US-A-3707433).These reflective layers are used primarily as a vapor shield, although they will improve the R-value of the insulated area if used in conjunction with an adjacent air space.

[0008] One of the main benefits of the present invention is that it utilizes commonly available building materials in its construction. There is no suggestion in any prior art teachings that a multiple layering principle, which uses common fiberglass and foil materials, would be of any advantage whatsoever for thermal building insulation. In fact, the prior art teaches just the opposite. It is common practice that if one were to add additional insulating batts to existing insulation that already include a vapor shield, the vapor shield on the added batt must be removed or slashed before installing.

[0009] Additionally, the prior art teaches that for a multiple-foil layer insulation to be effective, there must be an air space between the layers and that for optimum performance these spaces should be evacuated.

SUMMARY OF THE INVENTION

[0010] Although it is not fully understood, a simple laminated construction of several thin layers of batting material separated by reflective foil sheets provides a greatly improved R-value compared to similar material of exactly the same overall thickness and density. Furthermore and equally unexplained is the fact that this layering technique within a single batt of insulation shows to be a superior improvement, but primarily when applied to low density insulation. A higher density insulation in the area of 48 kg/m³ (3 lb./ft³) by weight does not benefit greatly from this layering structure. The present invention comprises the use of multiple, alternating layers of foil sheeting and fiberglass batting in a unitary batt of insulation. This produces surprising and unexpected results, especially when used with fiberglass insulation in the 9.6-24 kg/m³ (.6-1.5 lb./ft³) density range as will be more fully appreciated from the charts and graphs shown below.

BRIEF DESCRIPTION OF THE DRAWINGS

[0011] 

Figure 1 is an isometric view showing the simple multilayer structure of the present invention.

Figure 2 is a sectional view taken from Figure 1 showing the laminated structure of the insulation.

Figure 3 is a graph showing the relationship between R-value and spacing distances between low emissivity layers within an insulating space of given dimension.

Figure 4 is a graph showing the effect on R-value using different spacings within an insulating cavity of given dimension.

Figure 5 is a graph wherein the X-axis is the tested R-value of a standard Owens Corning (R) 9 cm (3.5-inch) wall insulation. The bar graphs depict the tested improvement in R-value of the test sample of the present invention, along with the calculated improvements that would be expected from 48 kg/m³ (3 lb./ft³) fiberglass and the 16 kg/m³ (1 lb./ft³) fiberglass used in the test sample of the present invention.

Figure 6 is a graph depicting the percentage reduction of temperature rise above ambient, provided by the test samples along with a corresponding indication of their approximate cost per square foot.

Figure 7 is a chart showing test results of the multilayer insulation of the present invention compared to standard batt insulation.

Figures 3a to 7a correspond to figures 3 to 7 but have imperial units of measure.

Figure 8 is a front view of one embodiment of the present invention utilizing three separate batts mounted side-by-side on a common sheet.

DESCRIPTION OF THE PREFERRED EMBODIMENT

[0012] One discovery of the present invention is that air spaces adjoining multiple reflective sheets can be replaced with low heat conductive material and retain superior resistance to radiative heat flow. A further benefit is that the system simultaneously limits heat flow be reducing conduction and convection.

[0013] Referring to Figure 1, the preferred embodiment of the present invention is structured as shown comprising a 7.6 cm (3-inch) batt of thermal insulation of the same dimension normally inserted between the wall studding in residential housing and other commercial structures. These dimensions include the standard width of 122 cm (48 inches) for metal commercial buildings or 39.4 cm (151/2 inches) for use with residential construction. Each insulation batt comprises at least three (3) sections, each section containing a layer of fiberglass insulation 1 with a sheet of aluminum foil 2 on at least one side. The fiberglass insulation used in the preferred embodiment is approximately 16 kg/m³ (1.0 lb./ft³) density. The sections are bonded together to form a unitary batt of insulation using special laminating techniques that will be discussed below.

[0014] The reflective material chosen for use in this invention may be selected from a wide variety of metal foils, foil laminates, metallized plastic films, metallized papers or other metallized substrates where the emissivity of these reflective surfaces is in the order of .2 or less. The metals may include gold, silver, tin, zinc, calcium, magnesium, chromium, antimony, platinum, copper, palladium, nickel and aluminum. These are all presently employed in the art of vacuum metallization and plating and can be obtained in the form of a foil. However, it is suggested that from a cost/performance standpoint, aluminum is the preferred metal to use either as a foil or vacuum deposited on the substrate. It should be noted that aluminum foil or vacuum deposited aluminum film can be readily obtained with an emissivity in the range of .03 to  .05, which is the preferred level. For reasons discussed below, it may be advisable that the reflective material employed in this invention be provided with an anti-oxidation coating prior to lamination.

[0015] Several types of low heat conductivity materials are commercially available, including rock wool and fiberglass, among others. Fiberglass blankets are particularly suited to this invention due to their strength, resistance to heat conductivity, damage resistance, flexibility, fire resistance, and because they are readily available in a wide range of widths, depths and densities.

[0016] Because one of the prime objectives of this invention is to provide insulation which is economical, it is important to point out that while simple 48 kg/m³ (3 lb./ft³) density fiberglass carries an R-value approximately 20% superior to that of 16 kg/m³ (1 lb./ft³) density, its cost is generally 300% higher. Furthermore, it has been unexpectedly found in laboratory tests that not only does an insulation of the type of the current invention using 16 kg/m³ (1 lb./ft³) density fiberglass possess an R-value superior to that of simple 48 kg/m³ (3 lb./ft³) fiberglass, but also that there appears to be no appreciable gain in R-value by using 48 kg/m³ (3 lb./ft³) density fiberglass in this invention (Figure 6). Therefore, because this invention performs optimally with the least expensive component, the user gains an R-value superior to that of 48 kg/m³ (3 lb./ft³) density fiberglass while incurring lower costs. From test results, it appears that the optimum density fiberglass for use with the present invention is in the range 9.6-24 kg/m³ (.6 to 1.5 lb/ft³).

[0017] The spacing between adjacent low emissivity sheets is critical. "Spacing" as used here means the depth of the fiberglass and hence the amount of space adjacent to the reflective sheets after the insulation has been installed. This spacing may change from the insulation at rest because the insulation may be compressed during installation and the spacings thereby reduced.

[0018] Spacings as low as 0.64 cm (.25 inches) have been tested and there are situations where this spacing is appropriate, although there is large drop-off in the performance of the system with spacings less than 1.28 cm (.50 inches), see Figure 3. The optimum spacing appears to be between 1.9 cm (.75 inches) and 5 cm (2.0 inches) depending upon the dimension of the insulating cavity and the R-value required. The number of sections used is equally critical and at least three sections are required to show marked improvement over existing insulation products.

[0019] As many as twelve sections have been tested and the optimum number appears to vary depending upon the specific requirements of the area being insulated. For example, an insulation of the present invention designed for use in a 7.6 cm (3-inch) cavity will be optimized by alternating 3 layers of 2.5 cm (1 inch), 16 kg/m³ (1 lb./ft³) density fiberglass with 4 sheets of low emissivity material.

[0020] Independent testing of the multilayer insulation system of the present invention was conducted at the Drexel University Center for Insulation Technology in Philadelphia, PA. Figure 7 shows the results of these performance tests. The multilayer insulating system was compared with standard batt insulation under identical test conditions. Tests #1, 2, and 4 were done on a 7.6 cm (3-inch) batt of the present invention. Test #3 was done on a 7.6 cm (3-inch) batt of the present invention compressed to a tickness of 5 cm (2 inches). Test #5 was done on a 11.4 cm (4.5-inch) batt of the present invention and test #6 and #7 were conducted for comparison purposes on a standard 9 cm (3.5-inch) Owens Corning (R) insulation batt. The "inverse sensitivities" indicate the dimension of the insulated cavity for each test.The multilayer insulation tested contained three layers of fiberglass insulation bounded by four sheets of aluminized mylar as shown in Figure 2.

[0021] Using the data presented in Figure 7, Figure 5 shows a bar graph which summarizes the test results. The multilayered insulation system of the present invention shows a surprising performance increase over standard insulation of 44.5% when used in a 7.6 cm (3-inch) insulating cavity and a 72.2% increase over standard insulation when used in a 12.7 (5-inch) insulating cavity. The standard insulation, which was used for comparison in these tests, was a 9 cm (31/2-inch) thick batt produced by Ownes Corning (R) which had a density of 12.5 kg/m³ (.78 lb/ft.³) at 9 cm (3.5 inches).

[0022] Since delamination of the sections will occur with the use of generally accepted foil/fiberglass bonding methods which employ a "dip and roll" laminator and a water-based adhesive, it is important that the present invention be formed using specialized techniques. It has been found that a successful and relatively inexpensive method of manufacture is to use a series of unwind-nipper-rewind laminators with a solvent based, pressure sensitive adhesive applied with a series of spray heads. This avoids the high cost of "hot melt" adhesives or multiple drying ovens which would make the present invention prohibitively expensive.

[0023] Another consideration in fabricating the insulation of the present type is that of oxidation of the metal surface of the low emissivity materials due to chemical interaction with the adhesive. If allowed to occur, this oxidation will increase the effective emissivity of the sheets and thereby dramatically reduce the effectiveness of the system.

[0024] A solution to this problem has been to coat the surface of the reflective material with an appropriate anti-oxidation substance prior to lamination.

[0025] It should be noted that insulation of the type of the present invention does not lend itself to a predictable straight-line calculation of R-value per inch as with most prior art insulation. Additionally, the depth of the spacings as well as the number of sections required to achieve optimization will vary with the dimension of the overall insulation cavity. For example, one cannot assume that because 2.5 cm (1-inch) spacing is the optimum for a 7.6 cm (3-inch) insulating cavity that 2.5 cm (1-inch) spacings is the optimum for a 15.2 cm (6-inch) cavity. Likewise, one cannot assume that because three sections is the optimum for the 7.6 cm (3-inch) insulating cavity that three sections is the optimum for the 15.2 cm (6-inch) cavity. It is highly recommended that the present invention be custom designed for each specific application.

[0026] By way of further describing the applicant's invention, it should be noted that it has been discovered that the intermediate sheets of low emissivity foil within the composite insulation batt do not adversely affect the insulation because of their function as vapor barriers. For best performance, these sheets should remain unperforated and continuous throughout the length of the insulation batt, contrary to the teachings in the prior art.

[0027] Furthermore, it should be understood that there may be many modifications and adaptations of the specific embodiment of the present invention as described herein and still fall within the scope of the invention as defined in the appended claims. It is therefore intended that the embodiment described herein not be a limitation on the scope of the invention which shall be determined by the appended claims.

[0028] For instance, three separate batts may be laminated side-by-side to a common sheet such that they may be installed between standard joists or studs three at a time. See Figure 8.

Claims

1. In a building structure, thermal insulation located within said building walls, ceilings or floors, the improved insulation, comprising; a unitary composite batt of thermal insulation consisting of multiple sections, each section comprising a layer of partially solid low-heat conductive material (1) and a sheet of low emissivity material (2) on at least one side, characterized in that said composite batt contains at least three of said sections but not more than eight sections laminated together wherein said layers of low heat conductive material (1) have a depth in the range of 6,4 mm (0,25 inches) to 50,8 mm (2,0 inches), said insulation occupying an unevacuated space at atmospheric pressure.

2. The building insulation of claim 1, characterized in that the low emissivity material is a metal foil (2) or metallized substrate with an emissivity ratio of 0,2 or less.

3. The building insulation of claim 2, characterized in that said low heat conductive material (1) is fiberglass or rock wool of an uncompressed density of 9,64 to 24,10 kg/m³ (0,6 to 1,5 lb. per cubic foot).

4. The building insulation of claim 3, characterized in that three seperate batts have been laminated to a final layer side-by-side such that they can be installed between standard building joists or studs, three at the time.

Ansprüche

1. Thermische Isolierung für Gebäude, die sich innerhalb der Gebäudewände, -decken oder -böden befindet, wobei die verbesserte Isolierung eine einheitliche, zusammengesetzte Lage einer Wärmeisolierung umfaßt, welche aus mehreren Abschnitten besteht, wobei jeder Abschnitt eine Schicht eines teilweise festen Materials (1) mit geringer Wärmeleitfähigkeit und eine dünne Lage eines Materials (2) mit geringem Emissionsvermögen auf mindestens einer Seite aufweist, dadurch gekennzeichnet, daß diese zusammengesetzte Lage mindestens drei dieser Abschnitte, aber nicht mehr als acht Abschnitte enthält, die laminiert sind, wobei die Schichten aus Material (1) mit geringer Wärmeleitfähigkeit eine Tiefe im Bereich von 6,4 mm bis 50.8 mm haben und die Isolierung einen nicht evakuierten Raum bei Atmosphärendruck einnimmt.

2. Gebäudeisolierung nach Anspruch 1, dadurch gekennzeichnet, daß das Material mitgeringem Emissionsvermögen eine Metallfolie (2) oder ein metallisiertes Substrat mit einem Emissionsvermögensverhältnis von 0.2 oder weniger ist.

3. Gebäudeisolierung nach Anspruch 2, dadurch gekennzeichnet, daß das leitende Material (1) mit geringer Wärmeentwicklung Glasfaser oder Steinwolle mit einer unverdichteten Dichte von 9,64 bis 24.10 kg/cm³ ist.

4. Gebäudeisolierung nach Anspruch 3, dadurch gekennzeichnet, daß drei getrennte Lagen nebeneinander zu einer fertigen Schicht laminiert wurden, sodaß drei auf einmal zwischen genormte Balken oder Pfosten installiert werden können.

Revendications

1. Isolation thermique pour murs, plafonds et planchers de bâtiments, ladite isolation perfectionnée comprenant une nappe composite unitaire d'isolation thermique et constituée par des ensembles multiples, chaque ensemble comportant une couche (1) de matériau à faible conduction thermique partiellement solide et une feuille d'un matériau à faible pouvoir émissif (2) sur au moins un côté, caractérisée en ce que la nappe composite comprend au moins trois ensembles et au plus huit ensembles stratifiés ensemble, dans laquelle lesdites couches de matériau à faible conduction thermique (1) présentent une profondeur comprise entre 6,4 mm (0,25 pouce) et 50,8 mm (2 pouces), ladite isolation occupant un espace non évacué et à pression atmosphérique.

2. Isolation pour bâtiments selon la revendication 1, caractérisée en ce que le matériau à faible pouvoir émissif est une feuille de métal (2) ou un substrat métallisé dont le pouvoir émissif est inférieur ou de l'ordre de 0,2.

3. Isolation pour bâtiments selon la revendication 2, caractérisée en ce que le matériau à faible conduction thermique (1) est de la fibre de verre ou laine de roche de densité non comprimée comprise entre 9,64 et 24,10 kg/m³ (0,6 à 1,5 livres par pied cubique).

4. Isolation pour bâtiments selon la revendication 3, caractérisée en ce que trois nappes distinctes sont stratifiées côte à côte en une couche finale, de façon qu'elles puissent être installées entre les traverses ou montants du bâtiment, trois à chaque fois.

Drawing